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ZweiKörperProblem

The ZweiKörperProblem refers to predicting the motion of two point masses interacting through Newtonian gravity. It is a foundational problem in celestial mechanics, illustrating how gravitational forces determine orbital motion and providing exact solutions for many practical situations, such as planets around the Sun or binary stars.

In the Newtonian framework, the problem can be reduced by moving to the center-of-mass frame and describing

The trajectory lies in a plane and can be written in polar form as r(θ) = p / (1

Applications include modeling planetary and binary-star orbits. The problem also serves as a baseline for perturbations

the
relative
coordinate
r
=
r2
−
r1.
The
two
bodies
are
equivalent
to
a
single
particle
of
reduced
mass
μ
=
m1
m2/(m1
+
m2)
moving
under
a
central
potential
V(r)
=
−
G
m1
m2
/
r.
The
resulting
equation
of
motion
for
the
relative
coordinate
is
d^2
r/dt^2
=
−
G
M
r
/
r^3,
with
M
=
m1
+
m2.
The
angular
momentum
h
=
|r
×
v|
is
conserved,
as
is
the
total
energy
E
=
1/2
μ
v^2
−
G
m1
m2
/
r.
+
e
cos
θ).
Here
p
=
h^2
/(G
M)
is
the
semilatus
rectum,
and
e
is
the
eccentricity
given
by
e^2
=
1
+
2
E
h^2
/(G
M)^2.
Negative
E
yields
elliptical
orbits
(including
circular
when
e
=
0),
E
=
0
parabolic,
and
E
>
0
hyperbolic
trajectories.
and
relativistic
effects,
which
introduce
phenomena
such
as
periapsis
precession
and
deviations
from
purely
Newtonian
behavior.